Abstract
Good lighting designs can establish suitable light environments in plant factories with artificial light (PFALs). This study used optical simulations to investigate the effects of lighting designs in PFALs on the coefficient of variation of light absorption (Φp; CV) of individual plants and the coefficient of utilization for the lighting system (U). Three-dimensional models of canola plants were constructed using a scanner, and a 3D model of the cultivation shelf was also created. The photosynthetic photon flux density (PPFD) distribution in the cultivation spaces, with or without the canola plants, was estimated first. The PPFD on the canola leaves was then estimated when the lighting design parameters, such as number, distance, height, radiant flux, and light distribution of the light-emitting diode lamps, were modified. The optical simulation showed good accuracy when estimating the PPFD distributions on the cultivation shelf and the leaves of the canola plants. The results showed that while the PPFD distribution across the growing area was uniform, it was not on a plant canopy. By appropriately controlling the layout of the lamps and their directionality, lighting designs that reduce Φp; CV and improve U in PFAL could be possible, and optical simulations could help to develop them.
Highlights
The interest in plant factories with artificial light (PFALs) has increased because of global climate change and concerns about food security and food supply [1]
Light emitting diodes (LEDs) and fluorescent lamps have been used as artificial light sources
The objective of this study was to investigate the effects of the lighting design of a PFAL on the variation of each plants light absorption and coefficient of utilization for the lighting system
Summary
The interest in plant factories with artificial light (PFALs) has increased because of global climate change and concerns about food security and food supply [1]. They have gained recognition from the food industry, as they supply plant products with a uniform quality year-round, that have the characteristics (taste, shape, and safety) desired by food industry users [2]. The cultivation environments in PFAL, including the light, air temperature, humidity, and gas concentrations surrounding the plants, can be controlled regardless of the outdoor environment [2,3]. With PFALs, the plants are surrounded by opaque walls, and the only light source is an artificial lamp. LEDs have attracted attention because of their higher efficiency for the conversion of electrical energy to radiation and the high level of control that can be exerted over their spectrum and intensity [2]
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